Scientists Grow Inexpensive High-End Photovoltaic Compounds

UC Berkeley engineers could help make high-end solar cells, currently used in satellites and other space and military applications, affordable for consumer markets.

In an effort to bring high-end photovoltaics to the masses, UC Berkeley scientists have developed an inexpensive way to grow indium phosphide, a III-V compound that is used in top of the line photovoltaics.

Engineers at the University of California, Berkeley, have developed an inexpensive new way to grow thin films of a material prized in the semiconductor and photovoltaic industries, an achievement that could bring high-end solar cells within reach of consumer pocketbooks.

“Performance is everything in the solar cell industry, but performance at a reasonable cost is key,” said Javey, who is also a faculty scientist at the Lawrence Berkeley National Laboratory. “The techniques we are reporting here should be a game-changer for III-V solar cells, as well as for LEDs.”

Top of the line photovoltaics are made from a class of material known as III-V (pronounced “three-five”) compounds, known for their superior efficiency at converting light into power. However, the complex manufacturing requirements for III-V materials make them up to 10 times more expensive than silicon, limiting their use to military applications and NASA satellites, the researchers said.

The UC Berkeley researchers demonstrated that indium phosphide, a III-V compound, could be grown on thin sheets of metal foil in a process that is faster and cheaper than traditional methods, yet still comparable in opto-electronic characteristics.

The paper’s co-lead authors from Javey’s lab are Rehan Kapadia, a recent Ph.D. graduate, and Zhibin Yu, a post-doctoral researcher.